EP1798067A1 - Tread pattern - Google Patents

Abstract

Running surface profile comprises two neighboring radially raised profile elements spaced from each other by a profile groove with a transversal stiffness distribution formed along the extension direction of the groove. A first section of the extension region of the profile element runs along the extension direction and the second section of the extension region of the profile element runs along the extension direction. The transversal stiffness is lower in the first section than in the second section. Preferred Features: The profile groove is a profile groove with a main extension direction with a direction component which is larger in the peripheral direction of the vehicle tire than the direction component in the axial direction.

Description

The invention relates to a tread pattern of a vehicle tire - in particular a pneumatic vehicle tire - with two adjacent by a tread groove spaced radially raised profile elements along the extension direction of the raised profile elements separating profile groove in the direction transverse to the tread groove differently shaped transverse stiffness distribution of a first of the two profile elements with at least a first Section of the extension region of the profile element along the extension direction of the tread groove and with at least a second portion of the extension region of the profile element along the extension direction of the tread groove, wherein the transverse stiffness of the profile element in the first section is less than in the second section.

In vehicle tires with tread pattern with several rows of profile blocks has already been proposed to influence the transverse stiffness of the profile block rows form the entire profile block row with different in the axial direction of the pneumatic vehicle tire and thus asymmetric flank angles. Likewise, it has already been proposed to form the shoulder profile block rows and further profile block rows of the tread pattern with different flank angles. With these measures, the transverse stiffness over the axial extent of the vehicle tire can be influenced. These measures lead to the defined increase in the transverse stiffness of entire profile block rows and can thus lead to the improvement of handling properties.

However, the individual design of the individual tread block elements does not find sufficient consideration here. Although the individual profile block elements are thus overall stiffer in terms of their transverse stiffness. The stiffness differences within a tread block element, however, are hardly affected by this. Abrasion differences due to such block-specific stiffness differences. Different abrasion within tread block elements can, in turn, in the long term during the life of the vehicle tire lead, for example, to a different grip on at least wet roads and also to reduced handling properties.

It has been proposed in such treads already raise the groove bottom of a tread groove between two separated by the tread groove profile block elements over the entire extension between the two tread block elements, so that a significant stiffening between the tread block elements is made possible. As a result, the handling properties can be improved. The rigid coupling between the tread block elements, however, ensures that the compensation of shear stresses during the flattening of the pneumatic vehicle tire when passing through the laces, which also adversely affects the abrasion of the tread block elements and the vehicle tire. The individual design of the individual profile block elements also does not find sufficient consideration here. The adjacent over the tread groove profile block elements are indeed stiffened against each other. However, the stiffness differences within a tread block element are hardly affected by this. Abrasion differences due to such block-specific stiffness differences. Different abrasion within tread block elements can, in turn, in the long term during the life of the vehicle tire lead, for example, to a different grip on at least wet roads and also to reduced handling properties.

The invention is based on the object in a simple manner abrasion and handling properties of a tread pattern of a vehicle tire - especially a pneumatic vehicle tire - with two adjacent by a tread groove spaced radially raised profile elements along the direction of extension of the raised profile elements separating profile groove in the direction transverse to the tread differently trained Transverse stiffness distribution of a first of the two profile elements with at least a first portion of the extension region of the Profile element along the extension direction of the tread groove and with at least a second portion of the extension region of the profile element along the extension direction of the tread groove, wherein the transverse stiffness of the profile element in the first section is less than in the second section to improve.

According to the invention, the object is achieved by forming a tread pattern of a vehicle tire - in particular a pneumatic vehicle tire - with two adjacent by a tread groove spaced radially raised profile elements along the extension direction of the raised profile elements separating profile groove in the direction transverse to the tread groove differently shaped transverse stiffness distribution of a first of the two Profile elements with at least a first portion of the extension region of the profile element along the extension direction of the tread groove and with at least a second portion of the extension region of the profile element along the extension direction of the tread groove, wherein the transverse stiffness of the profile element in the first section is less than in the second section, according to the features of Claim 1, wherein only along the first portion of the two sections of this first profile element in the radially inner n extension region of the tread groove is a stepped shoulder, starting from the first profile element formed transversely to the extension direction of the tread groove, which extends to stiffen in the direction of the second profile element in the tread groove and ends at a distance a with a> 0 from the second profile element in the tread groove. As a result, the profile element is additionally stiffened only in the region of lesser stiffness directed towards the profile groove while maintaining a decoupling to the adjacent profile element, whereby the profile element is made uniform in its rigidity while retaining the possibility of compensating the shear stresses when passing through the laces. The abrasion of the individual profile element is made uniform. The handling properties can also be improved in the long term.

The distance allows a tread groove effect into the profile bottom. In the case of very narrow tread grooves, the risk of the fullness of such tread grooves may be present Closing the tread groove during the passage of the laces are largely avoided.

Particularly advantageous is the training according to the features of claim 2, wherein the tread groove is a tread groove having a main extension direction, the direction component in the circumferential direction of the vehicle tire is greater than the direction component in the axial direction of the vehicle tire. This allows a particularly simple targeted equalization of the lateral stiffness of the profile element, a homogenization of the wear pattern and an improvement of the handling characteristics of the vehicle tire.

Particularly advantageous is the embodiment according to the features of claim 3, wherein at least the first raised profile element is a tread block element. Profile block elements are particularly susceptible to the effects of stiffness variability. The compensatory stiffening has a particularly strong effect on such training.

Particularly advantageous is the embodiment according to the features of claim 4, wherein at least the first raised profile element is a tread block element of a profile block row extended over the circumference of the vehicle tire.

Particularly advantageous is the training according to the features of claim 5, wherein the tread groove is a circumferentially extending over the circumference of the vehicle tire circumferential groove. In the case of this groove design, the lateral stiffness differences of the sections of the extension of the profile elements along the extension direction of the profile groove can be compensated particularly well by the use of the profile stiffening structure.

Particularly advantageous is the embodiment according to the features of claim 6, which is designed as a winter tire profile. Winter tires usually have a softer tread compound than a summer or all-season tire. In addition, winter tires have a high number of fine cuts in their profile elements. Both Design features allow high power transmission on low friction surfaces (eg, ice and snow), but on the other hand also provide a general reduction in tread rigidity, which generally manifests itself in inferior handling characteristics. Thus, it is particularly important in winter tires by the use of profile stiffening structures to compensate for the different lateral stiffness of the profile elements and thus to improve the handling and abrasion properties.

Particularly advantageous is the embodiment according to the features of claim 7, wherein the first - and in particular also the second - raised profile element is formed on its radially outer surface with one or more sipes. The use of fine sipes in the surface of the profile elements allows through a formation of edge effects better teeth with the ground, which increases the winter properties as well as the wet braking ability of a vehicle tire.

The embodiment according to the features of claim 8 is particularly advantageous, wherein the step-shaped shoulder, starting from the groove bottom, extends radially outward to a radial height h, for which: (0.1 t _m ) ≦ h ≦ (0.8 t _m ), in particular (0.2 t _m ) ≦ h ≦ (0.5 t _m ), where t _{m is} the average radial maximum groove depth t along the extension of the groove in its main extension direction in the extension region of the tread groove outside the first section in the vehicle tire in assembled standard state according to ETRTO standard

Particularly advantageous is the design according to the features of claim 9, wherein for a applies: wherein for the distance a is: 0.3mm ≤ a ≤ 20mm, in particular 0.4mm < a < 7mm. This embodiment also has the additional advantages, in particular in combination with the stiffening by a step-shaped shoulder, that the profile elements of the adjacent tread block elements can abut each other with small decoupling cuts a, in the flattened state of the tire, which improves the handling properties of the tire, as well as a Nutschließ safer at Abplatten and further profile deformation by lateral forces.

This has the effect that the profile block edges continue to be maintained for a meshing with the ground, especially on wintry road conditions. This improves the grip properties on winter road surfaces. A profile stiffening structure with stepped shoulder is particularly advantageous for narrower grooves when greater differences in stiffness between the profile elements must be compensated.

Particularly advantageous is the embodiment according to the features of claim 10, wherein the step-shaped step, starting from its radially outward, forming a plateau surface sloping down along the main extension direction of the tread groove in the groove bottom, wherein the stepped shoulder also along the sloping sloping Extending portion extends in the direction of the second profile element in the tread groove and ends at a distance a with a> 0 from the second profile element in the tread groove. This design allows a particularly good equalization of the lateral profile stiffness of the various sections along the groove.

Particularly advantageous is the training according to the features of claim 11, wherein the step-shaped step, starting from its radially outward, forming a plateau surface sloping transversely to the main extension direction of the tread groove in the groove bottom, and at a distance a with a> 0 from the second Profile element ends in the bottom of the tread groove. This embodiment is particularly advantageous for wider grooves, if the increase in stiffness of the profile stiffening structure is to take place continuously and the free groove cross section should not be restricted too much to increase the aquaplaning safety.

Particularly advantageous is the embodiment according to the features of claim 12, with a along the extension of the step-shaped shoulder changed trained distance a to the second profile element. This embodiment is particularly advantageous for wide grooves in addition to laterally very rigid block elements which have a different axial extension in the direction TA, if the equalization of the lateral profile stiffnesses of the various sections along the groove is to take place.

Fig. 1

Ausschnitt eines Laufflächenprofils eines Fahrzeugluftreifens in Draufsicht,

Fig. 2

Querschnittdarstellung des Ausschnitts des Laufflächenprofils von Fig. 1 gemäß Schnitt II-II von Fig. 1,

Fig. 3

Querschnittdarstellung des Ausschnitts des Laufflächenprofils von Fig. 1 gemäß Schnitt III-III von Fig. 1,

Fig. 2

Querschnittdarstellung des Ausschnitts des Laufflächenprofils von Fig. 1 gemäß Schnitt IV-IV von Fig. 1.

The invention will be explained in more detail below with reference to the embodiments schematically illustrated in Figures 1 to 4. Show in it

Fig. 1

Section of a tread pattern of a pneumatic vehicle tire in plan view,

Fig. 2

Cross-sectional view of the section of the tread pattern of Fig. 1 according to section II-II of Fig. 1,

Fig. 3

Cross-sectional view of the section of the tread pattern of Fig. 1 along section III-III of Fig. 1,

Fig. 2

Cross-sectional view of the section of the tread pattern of Fig. 1 according to section IV-IV of Fig. 1st

The tread pattern shown in Fig. 1 is a tread pattern of a pneumatic vehicle tire, which is designed in particular as a radial tire and is preferably a car tire or a tire for light commercial vehicles. The tread pattern is a tread pattern, which is particularly suitable for use in wintry driving conditions. In the following description, the tread pattern is considered across its width TA, which corresponds to the lathe width and thus the width of the ground contact patch of the pneumatic vehicle tire in the mounted, loaded operating condition under standard conditions (according to E.T.R.T.O.

In Figure 1, the axial direction A of the pneumatic vehicle tire is entered with arrow. Likewise, the circumferential direction U of the pneumatic vehicle tire is indicated by arrow.

The illustrated tread pattern is a directional bound shaped profile. That is, tires with this profile have a preferred unwinding direction, which is indicated in Fig. 1 by the arrow F, which points against the registered in Fig. 1 with arrow circumferential direction U, and therefore that such tires also according to their Abrollrichtung on the vehicle to be mounted.

The tread profile is arranged in the illustration of Fig. 1 in the axial direction from left to right one behind the other from a shoulder profile block row 1 a block profile 2, a profile rib 3, a profile rib 4, a profile block row 5 and a shoulder profile block row 6, respectively in the circumferential direction U on the entire circumference of the pneumatic vehicle tire are extended. The profile ribs 3 and 4 are formed over the entire circumference of the pneumatic vehicle tire and formed axially separated from each other by an over the entire circumference extending circumferentially oriented circumferential groove 9 separately. In the illustrated embodiment, the equatorial plane of the tire extends in the axial center of the circumferential groove 9.

The illustrated tread pattern is formed symmetrically to the equatorial plane, wherein the formed in Fig. 1 right of the equatorial plane tire profile half formed by mirroring the left tire tread half at the equatorial plane and by subsequent displacement in the circumferential direction U.

The shoulder profile block row 1 is composed of a plurality of circumferentially U successively arranged profile block elements 31, the profile block row 2 of a plurality of circumferentially U successively arranged profile block elements 32, the profile block row 5 of several circumferentially U successively arranged profile block elements 35 and the shoulder profile block row 6 of several circumferentially U arranged one behind the other Profile block elements 36 formed.

Starting from the rib 3, a plurality of distributed over the circumference of the vehicle pneumatic tire in the circumferential direction U arranged one behind the other transverse grooves 12 extending axially from the profile rib 3 axially outward over the axial extent of the profile block row 2 and the axial extent of the shoulder profile block row 1 to extend the left shoulder into it. In the process, each of the transverse grooves 12 in the region of the profile block row 2 separates two profile block elements 32 arranged one behind the other in the circumferential direction U from each other and in the region of the shoulder profile block row 1 two profile block elements 31 arranged one behind the other in the circumferential direction U. Likewise, starting from the tread rib 4 more extend over the Scope of the pneumatic vehicle tire distributed in the circumferential direction U successively arranged transverse grooves 13, each extending axially from the profile rib 4 axially outward over the axial extent of the profile block row 5 and the axial extent of the shoulder profile block row 6 into the right shoulder. In the process, each of the transverse grooves 13 in the region of the profile block row 5 separates two profile block elements 35 arranged one behind the other in the circumferential direction U and two profile block elements 36 arranged one behind the other in the circumferential direction U in the region of the shoulder profile block row 6. The transverse grooves 12 and 13 are formed in their axially inner extending to the equatorial plane extending region near the respective adjacent tread rib 3 and 4 with a axially inwardly from the equatorial plane axially outward slope to the axial, the peripheral component along the axial extent of the transverse grooves 12th or 13 in each case continuously decreases from axially inward to axially outward to the edge of the axial extension of the ground contact surface TA.

Between two in the circumferential direction U successively arranged transverse groove 12 are each a profile block element 31 of the shoulder profile block row 1 and a profile block element 32 of the profile block row 2 axially separated by a the two transverse grooves 12 connecting rectilinear profile groove 7 from each other. The tread block element 32 is axially separated from the tread block rib 3 by a serrated profile groove 8. Between two in the circumferential direction U successively arranged transverse grooves 13 is a respective profile block element 35 of the profile block row 5 and a profile block member 36 of the shoulder profile block row 6 axially separated by a the two transverse grooves 13 connecting rectilinear profile groove 11. The tread block element 35 is axially separated from the tread rib 4 by a serrated profile groove 10.

The flanks 23 of the profiled rib 3 pointing to the left shoulder and the flank 24 of the profiled rib 4 pointing to the right shoulder are formed in the circumferential direction U in a V-shape from axially inward to outward, wherein in each case within the extension region extending in the circumferential direction U. the axially inwardly facing flank 25 of the profile block elements 32 to the left shoulder pointing flank 23 of the profile rib 3 and within the extending in the circumferential direction U extending portion of the axially inwardly facing edge 26 of the profile block elements 35 of the profile row 5 to the right shoulder facing edge 24 of the profile rib 4 a short peripheral portion with axially inwardly offset 27 and 28 with axially inwardly directed pitch component. Corresponding to the resulting zig-zag shape of the axially outwardly facing edge 23 of the tread rib 3 and the axially outwardly facing edge 24 of the tread rib 4 is in each case the axially inwardly directed flank 25 of the profile block elements 32 and the axially inside directed edge 26 of the profile block elements 35 formed serrated, wherein - as can be seen in Fig. 1 - in the rolling direction F behind the offset 27 and 28 formed extension region of the tread groove 8 and the tread groove 10, the tread groove 8 and the tread groove 10th each with a smaller each measured transversely to the extension direction of the tread groove 8 and the tread groove 10 groove width than in the formed in the rear of the position of the offset extension area.

The tread grooves 7 and the tread grooves 11 are formed in their inclination curve to the axial A such that the tread grooves 7 and 11 seen in the rolling direction F have a V-shaped groove profile running apart axially.

As stated, illustrated in Fig. 1 embodiment of a tread pattern is a symmetrical profile. The further explanation is therefore limited to the description of the profile half shown in Fig. 1 right of the equatorial plane.

The profile grooves 11 have in the radially outer extension region of the profile block elements 35 and 36 over their entire extent along their main extension direction each have a straight course of their groove flanks and also a straight course of the groove bottom and are formed along its main extension with a groove depth t, the groove depth t respectively represents the maximum extent of the radial extent of the radially outer surface of the tread block elements 35 and 36 in the radial direction inwardly to the groove bottom. The profile block elements 36 have, due to rolling direction F from axially inside to axially outside seen inclination of the tread groove 11 starting from a maximum extent c of its axial extent to the axially outer edge of the width of the ground contact surface TA a continuously decreasing axial extent range of its axial width to the axially outer edge of the width of the ground contact surface TA, which at the end seen in the rolling direction F end of the tread groove 11 only a measure b of its axial width to the axially outer edge of the width of the ground contact surface TA is, with b <c. In the tread groove 11 having a total extension length p along its main extension direction, along its main extension direction, in a roll extension direction F of the tread groove 11, there is an extension length q of (0.2p) ≤ q ≤ (0.75p) at each tread block element 36 in FIG a reinforcing step 21 is formed, which extends transversely to the main extension direction of the tread groove 11 to a distance a to the flank of the axially adjacent tread block element 31, wherein for a: a> 0. The distance a is selected so that applies to him: 0.3mm ≤ a ≤ 20mm. In a particular embodiment, a is chosen such that for a: 0.4 mm ≦ a ≦ 7 mm. In the example shown, a = 1.2mm.

As shown in FIG. 3, the stiffening step 21 extends radially outward from the groove bottom to a radial height h, where h is equal to: (0.1 t _m ) ≦ h ≦ (0.8 t _m ) , In a particular embodiment, (0.2 t _m ) ≦ h ≦ (0.5 t _m ), where t _{m is} the average radial maximum groove depth t along the extension of the groove in its main extension direction in the extension region of the tread groove outside the first section at the Vehicle tires in assembled standard state according to ETRTO standard.

The cross section of the stiffening stage 21 is shown in FIG. It can be seen that the stiffening stage 21 has a plateau at its radially outer surface.

Analogous to the stiffening stage 21 in the groove 11, as shown in FIGS. 1 and 3, a stiffening stage 20 is also formed in the groove 10 on the profile block element 35. The stiffening stage 20 is formed in each case in the axial extension region of the groove 10, which extends between the corresponding to the offset 28 of the flank 24 of the profile rib 4 formed offset the flank 26 of the tread block element 35 and extending in the rolling direction F the offset transverse groove 13 extends. In this extension region of the groove 10, the groove is formed with a groove width e measured in the radially outer surface of the tread rib 4 and the tread block member 35 perpendicular to the main extension direction of the groove. The stiffening stage 20 extends in each case transversely to the main extension direction of the profile groove 10 as far as a distance a from the flank 24 of the axially adjacent profile rib 4, where a is valid for a: a> 0. The distance a is chosen such that it has the following value: 0, 3mm ≤ a ≤ 20mm. In a particular embodiment, a is chosen such that for a: 0.4 mm ≦ a ≦ 7 mm. In the example shown, a = 0.8 mm. Along this extension region of the groove 10, the groove is formed between the transverse groove 13 formed in the axial extension region of the tread block element 35 with still relatively large circumferential direction component and the groove 10 with a smaller average axial extent (in the axial direction A of the pneumatic vehicle tire) of the tread block element 35 than in FIG in the rolling direction F the offset of the flank 26 of the profile block element 35 upstream extension area.

As shown in Figures 1 and 4, in addition, in the subsequent to the axially inner end of the transverse groove 13 in the rolling direction F the offset 28 of the edge 24 of the tread rib 4 respectively upstream extension portion of the groove 10, a stiffening stage 22 to the edge 24 of Tread rib 4 formed in the region of the offset 28, which extends transversely to the main extension direction of the tread groove 10 to a distance a to the flank 26 of the axially adjacent tread block element 35, wherein for a: a> 0. The distance a is chosen so that for him: 0.3mm < a < 20mm. In a particular embodiment, a is chosen such that for a: 0.4 mm < a < 7 mm. In the example shown, a = 0.8 mm. As can be seen in Fig. 4, the stiffening step 22 extends from the offset 28 in the direction of extension of the groove 10 in the direction of the tread groove 13 over an extension length d. where for d: d> 0 to then pass over a ramp-shaped depression in the groove bottom of the groove 10. The extension length d is selected such that for d: (0.2 e) ≦ d ≦ (2 e), where e - as described above - the groove width of the groove 10 in the radially outer surface of the Tread rib 4 and the profile block member 35 in the rolling direction F the offset 28 downstream extension portion of the groove.

LIST OF REFERENCE NUMBERS

1

Schulterprofilblockreihe

2

Profilblockreihe

3

Profilrippe

4

Profilrippe

5

Profilblockreihe

6

Schulterprofilblockreihe

7

Profilrille

8

Profilrille

9

Umfangsprofilrille

10

Profilrille

11

Profilrille

12

Querrille

13

Querrille

14

Feineinschnitt

15

Feineinschnitt

16

Feineinschnitt

17

Feineinschnitt

18

Feineinschnitt

19

Feineinschnitt

20

Versteifungsstufe

21

Versteifungsstufe

22

Versteifungsstufe

23

Flanke

24

Flanke

25

Flanke

26

Flanke

27

Versatz

28

Versatz

31

Profilblockelement

32

Profilblockelement

35

Profilblockelement

36

Profilblockelement

(Part of the description)

1

Shoulder profile block row

2

Profile block row

3

profile rib

4

profile rib

5

Profile block row

6

Shoulder profile block row

7

tread groove

8th

tread groove

9

Scope tread groove

10

tread groove

11

tread groove

12

transverse groove

13

transverse groove

14

sipe

15

sipe

16

sipe

17

sipe

18

sipe

19

sipe

20

stiffening stage

21

stiffening stage

22

stiffening stage

23

flank

24

flank

25

flank

26

flank

27

offset

28

offset

31

Profile block element

32

Profile block element

35

Profile block element

36

Profile block element

Claims (12)

Tread pattern of a vehicle tire - especially a pneumatic vehicle tire - with two adjacent by a tread groove spaced radially raised profile elements along the direction of extension of the raised profile elements separating profile groove in the direction transverse to the profile groove differently shaped transverse stiffness distribution of a first of the two profile elements with at least a first portion of the extension region of the Profile element along the extension direction of the tread groove and with at least a second portion of the extension region of the profile element along the extension direction of the tread groove, wherein the transverse stiffness of the profile element in the first section is less than in the second section,
wherein only along the first portion of the two sections of this first profile element in the radially inner extension region of the tread groove, a stepped shoulder is formed starting from the first profile element transversely to the extension direction of the tread groove, which extends to stiffen in the direction of the second profile element in the tread groove and in a Distance a with a> 0 ends from the second profile element in the tread groove. Tread pattern according to the features of claim 1,
wherein the tread groove is a tread groove having a main extension direction whose direction component in the circumferential direction of the vehicle tire is greater than the direction component in the axial direction of the vehicle tire. Tread pattern according to the features of claim 1 or 2,
wherein at least the first raised profile element is a tread block element. Tread pattern according to the features of one or more of the preceding claims,
wherein at least the first raised profile element is a profile block element of a over the circumference of the vehicle tire extended profile block row is. Tread pattern according to the features of one or more of the preceding claims,
wherein the tread groove is circumferential groove extending over the circumference of the vehicle tire. Tread pattern according to the features of one or more of the preceding claims,
which is designed as a winter tire profile. Tread pattern according to the features of one or more of the preceding claims,
wherein the first - and in particular also the second - raised profile element is formed on its radially outer surface with one or more sipes. Tread pattern according to the features of one or more of the preceding claims,
wherein the step-shaped shoulder extending radially outward from the groove bottom to a radial height h, for which applies: (0.1 t _m ) ≤ h ≤ (0.8 t _m ), in particular (0.2 t _m ) ≤ h ≤ (0.5 t _m ), where t _{m is} the average radial maximum groove depth t along the extension of the tread groove in its main extension direction in the extension region of the tread groove outside the first section in the vehicle tire in the mounted standard ETRTO standard condition. Tread pattern according to the features of one or more of the preceding claims,
where the distance a is: 0.3mm ≤ a ≤ 20mm,
in particular 0.4mm ≤ a ≤ 7mm. Tread pattern according to the features of one or more of the preceding claims,
wherein the step-shaped step, starting from its radially outward, a plateau-forming surface ramps down along the main extension direction of the tread groove in the groove bottom, wherein the step-shaped shoulder also extends along the ramp-shaped extending portion in the direction of the second profile element in the tread groove and in a distance a with a> 0 ends from the second profile element in the tread groove. Tread pattern according to the features of one or more of the preceding claims,
wherein the step-shaped step, starting from its radially outwardly directed, forming a plateau surface sloping transversely to the main extension direction of the tread groove in the groove bottom, and ends at a distance a with a> 0 from the second profile element in the bottom of the tread groove. Tread pattern according to the features of one or more of the preceding claims,
with a distance along the extension of the step-shaped shoulder formed a distance a to the second profile element.

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